Living in the Environment

Slides:



Advertisements
Similar presentations
Energy! The ability to do work.
Advertisements

Environmental Systems: Chapter 2-
Matter and Energy.
CHEMISTRY OF LIVING THINGS Chapter 2. © 2004 Delmar Learning, a Division of Thomson Learning, Inc. CHEMISTRY Defined as the study of the structure of.
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 13 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 13.
Science, Matter, Energy, and Systems Chapter 2. Core Case Study: Carrying Out a Controlled Scientific Experiment  F. Herbert Bormann, Gene Likens, et.
Environmental Systems: Chapter 2-
Science, Matter, Energy, and Systems Chapter 2 Dr. Wesam Al Madhoun.
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 12 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 12.
MATTER AND ENERGY CHAPTER TWO. Concepts Matter consists of elements and compounds, which in turn are made up of atoms, ions, or molecules Whenever matter.
Mr. Clark Bethpage HS AP Environmental Science
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 13 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 13.
Science, Matter, and Energy Chapter 2. Science Focus: Easter Island  Solving a mystery Population crash – cause and effect  Evolving hypotheses Unsustainable.
Chapter 2 Science, Systems, Matter, and Energy. Feedback Loops: How Systems Respond to Change  Outputs of matter, energy, or information fed back into.
Science. Matter. Energy. Systems.
Science, Matter, Energy, and Systems
Core Case Study: Carrying Out a Controlled Scientific Experiment
Science, Matter, and Energy
Science, Systems, Matter, and Energy Chapter 3.  Science as a process for understanding  Components and regulation of systems  Matter: forms, quality,
Science, and Critical Thinking Science is an attempt to discover order in nature and use that knowledge to make predictions about what is likely to happen.
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 13 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 13.
Science, Matter, and Energy Chapter 2 An Environmental Lesson from Easter Island- Tragedy of the Commons Colonized about 2,900 years ago Colonized about.
Matter, Energy, and Life. Matter: Forms, Structure, and Quality ■ Element: building blocks of matter ■ Compound: two or more elements combined ■ Atom:
Science, Matter, Energy, and Systems
Science, Matter, and Energy Chapter 2. WHAT DO SCIENTISTS DO?
Science, Systems, Matter, and Energy Chapter 3 APES Ms. Miller Chapter 3 APES Ms. Miller.
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 14 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 14.
LIVING IN THE ENVIRONMENT 17 TH MILLER/SPOOLMAN CHAPTER 2 Science, Matter, Energy, and Systems.
+ Chapter 3 Science, Systems, Matter and Energy. + What is Energy? The capacity to do work and transfer heat Kinetic Energy Matter has because of its.
Energy Notes.
Science. Models, systems “Scientific knowledge is a body of statements of varying degrees of certainty – some most unsure, some nearly sure, and none absolutely.
Ch 2 Science, Systems, Matter, and Energy. Case Study Easter Island (Summarize):
Energy and Matter Chapter 2.. Review!  Easter Island:  Colonized about 2,900 years ago  Soil and tree resources exhausted (Natural Capital)  Over.
CHAPTER 2 Science, Matter, Energy, and Systems
Science, Matter, and Energy Chapter 2. Question of the Day Easter Island and the civilization that once thrived and then largely disappeared is an example.
Chapter 2 Science, Systems, Matter, and Energy. Core Case Study: Environmental Lesson from Easter Island  Thriving society 15,000 people by ,000.
Environmental Systems
© Cengage Learning 2015 LIVING IN THE ENVIRONMENT, 18e G. TYLER MILLER SCOTT E. SPOOLMAN © Cengage Learning Science, Matter, Energy, and Systems.
Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 14 th Edition Chapter 3 G. Tyler Miller’s Living in the Environment 14.
Chapter 3: Science, Systems, Matter and Energy “Science is an adventure of the human spirit. It is essentially an artistic enterprise, stimulated largely.
Environmental Systems
Look at these two sets of animal tracks. List 3 OBSERVATIONS Make an INFERENCE.
Chapter 1 Review  Key Concepts we have covered so far.
Science, Systems, Matter, & Energy Chapter 2 AP Environmental Science Ms. C. Johnson Period 1.
Science, Matter, and Energy
ENVIRONMENTAL SCIENCE
Chapters 9 & 10 Energy.
Science, Matter, Energy, and Systems
Review of Basic Science Concepts
Energy.
Science, Matter, Energy, and Systems
Chemistry Pre-Quiz!.
Chemistry Pre-Quiz!.
Science, Matter, Energy, and Systems
Environmental Systems
Science. Matter. Energy. Systems.
Chapter 2 The Basics of Life
Basic Chemistry Review for APES What is MATTER? What is Energy?
Energy Notes.
Science, Systems, Matter, and Energy
MATTER AND ENERGY CHAPTER THREE.
Review Information: We will NOT discuss these sections in class!
G. Tyler Miller’s Living in the Environment 13th Edition Chapter 3
CHAPTER 2 SCIENCE, MATTER, ENERGY & SYSTEMS.
Science, Systems, Matter, and Energy
Science, Matter, Energy, and Systems
Energy Conservation Home, School, and Transportation
Unit 1 What is Ecology? Chapters 1 & 3 Chapter 3.
Matter.
Science, Matter, Energy, and Systems
Presentation transcript:

Living in the Environment A Quick Review of Basic Concepts in Science, Systems, Matter, and Energy G. Tyler Miller’s Living in the Environment 14th Edition Chapter 3

Key Concepts Science as a process for understanding Components and regulation of systems Matter: forms, quality, and how it changes; laws of matter Energy: forms, quality, and how it changes; laws of energy Nuclear changes and radioactivity

The Nature of Science Science is an attempt to discover order in the natural world and use the knowledge to describe what is likely to happen in nature GOAL: to increase our understanding of our world Based upon the scientific process

The Nature of Science Attempt to solve a problem Follow the process and repeat!

Three critical components to any “good science” The Nature of Science Three critical components to any “good science” Skepticism: Do not believe what you see until verified Reproducible: data and results should be able to be done over and over Peer Review: other scientists must review work (vs. “Junk science”)

Science, and Critical Thinking Ask a question Do experiments and collect data Formulate hypothesis to explain data Do more Experiments to test hypothesis Revise hypothesis if necessary Well-tested and accepted hypotheses become scientific theories Interpret data accepted patterns In data become scientific laws Scientific data Scientific hypotheses: IF…THEN…BECAUSE… Scientific (natural) laws Scientific theories Frontier science Junk Science Fig. 3-2 p. 33

The Nature of Science Scientists can do 2 major things: Attempts to disprove things Can establish that a particular model, theory, or law has a high degree of certainty of being true. NOT ABSOLUTELY TRUE Scientists should not say “Cigarettes Cause Cancer” but can say “There is overwhelming evidence (SUPPORTS/ DOES NOT SUPPORT!) from thousands of studies that indicate a relationship between cigarette usage and lung cancer”

Models and Behaviors of Systems Any action in a complex system has multiple, unintended, and often unpredictable effects. Regulation of systems Positive and Negative Feedback loops Examples??? Synergy

Negative feedback loop

Positive feedback loop

Matter: Forms, Structure, and Quality What do these terms mean? Elements Compounds Atoms Ions Molecules

Atoms Subatomic Particles Protons Neutrons Electrons Atomic Characteristics Isotopes Hydrogen 1, 2 and 3 Atomic number Carbon # 6, Uranium #92 Atomic mass Uranium 235 Ion Lost or gained e-

Examples of Isotopes Fig. 3-5 p. 40

Acids: 0 – 6.9 Neutral 7.0 Alkaline (Basic) 7.1 – 14 pH Measures acidity or alkalinity of water samples Scale 0 – 14 Acids: 0 – 6.9 Neutral 7.0 Alkaline (Basic) 7.1 – 14 Testing your Soil pH for growth of plants video

Chemical Bonds - Animations Chemical formulas Ionic bonds Covalent bonds

Organic Compounds: CARBON Organic vs. inorganic compounds Hydrocarbons Chlorinated hydrocarbons Simple carbohydrates Complex carbohydrates Proteins Nucleic acids

High quality (more concentrated) vs. Low Quality Matter (more diluted) Matter Quality – how useful it is as a resource; based on availability and concentration High quality (more concentrated) vs. Low Quality Matter (more diluted) Material Efficiency (Resource productivity) – total amount of material needed to produce each good Fig. 3-8 p. 43

Energy Capacity to do “work” and transfer heat Types: Kinetic (Heat, electricity) Potential (stored) Radiation: Energy & Wavelength

Electromagnetic Spectrum Some energy travels in waves at the speed of light Ionizing Radiation – Enough energy to knock e- from other atoms, changing them to positively charged particles; damaging to cells Fig. 3-9 p. 44

Transfer of Heat Energy Convection Conduction Radiation Heat from a stove burner causes atoms or molecules in the pan’s bottom to vibrate faster. The vibrating atoms or molecules then collide with nearby atoms or molecules, causing them to vibrate faster. Eventually, molecules or atoms in the pan’s handle are vibrating so fast it becomes too hot to touch. As the water boils, heat from the hot stove burner and pan radiate into the surrounding air, even though air conducts very little heat. Heating water in the bottom of a pan causes some of the water to vaporize into bubbles. Because they are lighter than the surrounding water, they rise. Water then sinks from the top to replace the rising bubbles.This up and down movement (convection) eventually heats all of the water. Heat: total kinetic energy of all moving atoms in a substance.

Energy: Quality (ability to do work) High-quality energy Low-quality energy Fig. 3-12 p.46

Changes in Matter Physical: composition unchanged (water and steam) Chemical: change in the composition of elements or compounds.

Chemical Reactions Fig. In text p. 47

The Law of Conservation of Matter Matter is not destroyed Matter only changes form There is no “throw away”

Matter and Pollution Chemical nature of pollutants – severity based on chemical nature, concentration and persistence. Concentration (ppm – 1 part pollutant per million parts gas, water etc; ppb, ppt) Persistence Degradable (non-persistent) Biodegradable - bacteria Slowly degradable (persistent) pollutants – DDT, plastics Nondegradable (persistent) – lead, mercury arsenic

Great Pacific Garbage Patch Lead Poisoning and Gold Mining

Half-life Fig. 3-13, p. 49

Radioactive Isotopes Examples: Iodine - 131 (131I): injected into humans to study the function of the thyroid gland. Can be seen through special equipment that picks up on the radiation energy given off by this isotope as it travels through the body. Carbon-14 (14C): used to treat brain tumors and track the ages of trees and fossils.

Nuclear Reactions Fission Fusion Fig. 3-15 p. 50 Fig. 3-16 p. 50

Half life Problems!

First Law of Thermodynamics (Energy) Energy is neither created nor destroyed Energy only changes form You can’t get something for nothing ENERGY IN = ENERGY OUT

Second Law of Thermodynamics In every transformation, some energy is converted to heat (lost) You cannot break even in terms of energy quality